Systems, devices, and methods for providing multiple services to premises over communication networks

ABSTRACT

Methods, systems, and devices for providing one or more virtual networks for a plurality of services are disclosed. The device may include a secure access node coupled to a wide area communication network and a premises communication network. The secure access node may have a node software platform, one or more node processors, a node storage device, and one or more node communication interfaces. Further, the secure access node may receive a plurality of data packets through one of the one or more node communication interfaces. The node software platform may execute on one of the node processors and may include a node deep packet inspection engine, a node rules generation engine, a node rule check and notification generation engine, a node service segregation engine, a node communication software application, and a node service adapter software application.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority under the laws and rules of the United States, including 35 USC §120, to U.S. patent application Ser. No. 12/835,963. The contents of U.S. patent application Ser. No. 12/835,963 is herein incorporated by reference.

BACKGROUND

An individual using a computer, Smartphone, or gaming system may subscribe to multiple services from across the Internet to enhance the individual's quality of life or increase efficiency in work. Examples of such services may include controlling banking and financial activity, conducting e-commerce, managing premise security and energy consumption, Internet gaming as well as other services. Alternatively, businesses using computers and other electronic equipment may also subscribe to multiple services from across the Internet including managing business content, controlling financial transactions, office security, energy consumption as well as other services. Many of these services may require the consumer (e.g. an individual at home or employee of a business) to initiate a virtual network between a terminal network device having client service software application and a service provider server to control and manage the virtual network. Thus, either terminal network device or service provider server or both must maintain the service virtual network. Such a scheme of generating a service virtual network may be inefficient in using network resources as well as expensive in both time and cost to implement such virtual network management and control features into each terminal network device or each service provider server.

SUMMARY

An individual or a family at home is increasingly facing needs to subscribe to multiple services from service providers to enhance the individual's (or family's) quality of life, increase efficiency of work or enjoy enhanced safety or security. Business entities are also experiencing similar needs. Examples of such services may include conducting banking transactions, engaging in e-commerce, managing premises security, controlling energy consumption, gaming etc. The individuals at home or in business generally use a computer, a Smart phone, gaming system or any other electronic equipment to access the services or control the proper usage of such services. The service providers in many instances may need access to resources at home or business premises in order that they may provide services. For instance, in providing energy management services, access to energy consuming elements such as home appliances may be needed. To obtain access to resources on the premises, a terminal or end point device may need to be installed at the premises and the terminal device may need a tethered or non-tethered connection to the controlled appliances. Different functions in the terminal device may be accessible by different service providers in a seamless and secure way. Further, one service provider may not be allowed to interfere with the workings or services of other service providers on the same terminal device. Each service provider may have required access to and control of elements (e.g. appliances, etc.) at home which are in the service provider's domain of access, but not in any other domain. Generally, service providers may deploy a server or server function hosted in a public server or Cloud computer to control functions at the premises that may access the elements at the premises through the terminal device at the premises. Consequently, there may be multiple virtual service networks in operation, each virtual service network comprising of a server controlled or managed by a service provider and a subset of functions in the terminal device, the subset functions providing access to the elements in the premises which are in the domain of the particular service (e.g. appliances, etc.). The connection between the servers controlled or managed by the service providers and the terminal device may be hard-wired, connected through the Internet or some other communication network that may include a wireline network, a cable network or a wireless network. The connection between the terminal device at the premises and the elements (e.g. appliances, etc.) in the premises may be hard-wired or through a wireless network using WIFI or Zigbee or other wireless protocols. The present application discloses systems, devices and methods for generating and operating multiple virtual networks which are cost-effective, easy to administer and expand, and secure from third party interference as well as from cross service domain (cross virtual network) interference

Traditionally, terminal network devices and/or service provider servers together form, control, and maintain specific virtual networks for the benefit of a community which requires access to a communication network for business or entertainment. Providing, generating and maintaining simultaneous multiple networks for multiple services may encompass the same set of clients (terminal or end point devices) such that different service providers may provide different services to the clients. Current implementation paradigms may be inefficient and expensive in providing, generating and maintaining simultaneous multiple networks for multiple services. The present application discloses systems, devices, and methods for providing multiple virtual networks for multiple services while maintaining or enhancing the level of security of traditional individual networks currently provide. The disclosed systems, devices, and methods generate such multiple secure virtual networks for providing different services controlled by different service providers by using intermediate network nodes which generate, control, and maintain virtual service networks for individual and business consumers. The intermediate nodes may be customer premises equipment or a server of a primary service provider (e.g. cable television or telephone service provider). The intermediate nodes may be controlled by the primary service provider and the intermediate nodes may ensure that other service providers have access to network resources controlled by the primary service provider in a specified and secure manner for the benefit of the end user community. While maintaining these multitudes of virtual service networks, the intermediate network nodes may inspect received data packets of different services and collect data and other information (e.g. time of day) from the received data packets. Consequently, the intermediate nodes may process the collected data to ensure and maintain segregation between services, increase security from third party intrusion into the virtual service networks, generate additional robust service features by analyzing data across different services, and may provide consumer behavioral data to enhance e-commerce activities including advertising if the user permits. Service segregation provides not only the ability of service providers to operate in separate domains, but also enables sharing of common facilities for regulated and non regulated services. In addition to the above-mentioned benefits, having virtual network management and control for multiple services implemented by intermediate nodes in a network such as several primary servers (e.g. primary service provider server) or several customer premises equipment, has the further advantages of having the virtual network management and control mechanism residing in only a few intermediate nodes rather than a comparatively larger number of terminal network devices (e.g. end point devices) and service providers servers (e.g. secondary servers).

Within the embodiments described below, an exemplary system for providing one or more virtual networks for a plurality of services is disclosed. The system includes a primary server executing a server software platform with the primary server coupled to a wide area communication network and having one or more server processors, a server storage device, and one or more server communication interfaces. The primary server may receive a plurality of data packets through a server communication interface. Further, the system may include one or more secure access nodes (e.g. customer premises equipment), each one of the secure access nodes may be coupled to a wide area communication network as well as to a premises communication network. Each of the secure access nodes may have a secure access control module executing a node software platform and one or more service modules, each service module executing a module software platform. Moreover, each secure access control module may include one or more node processors, a node storage device, and one or more node communication interfaces. The secure access control module may receive a plurality of data packets through one of the node communication interfaces. Additionally, each service module may include one or more module processors and a module storage device.

The server software platform may include a server deep packet inspection engine, a server rules generation engine, a server rule check, and notification generation engine, a server service segregation engine, a server communication software application, and a server service adapter software application. Further, the node software platform may include a node deep packet inspection engine, a node rules generation engine, a node rule check, and notification generation engine, a node service segregation engine, a node communication software application, and a node service adapter software application. In addition, the module software platform may include a module communication software application Also, the server rule generation software application and the node rule generation software application may be implemented using one or more fuzzy logic algorithms and the server rule check software application and the node rule check software application may be implemented using one or more fuzzy logic algorithms.

Within the embodiments described below, an exemplary device for providing one or more virtual networks for a plurality of services is disclosed. The device may include a secure access node coupled to a wide area communication network and to a premises communication network. Further, the secure access node may have a secure access control module executing a node software platform and one or more service modules executing a module software platform. In addition, the secure access control module may include one or more node processors, a node storage device, and one or more node communication interfaces. The secure access control module may receive a plurality of data packets through one of the node communication interfaces. Also, each one of the service module may include one or more module processors and a module storage device. Moreover, the node software platform may include a node deep packet inspection engine, a node rules generation engine, a node rule check, and notification generation engine, a node service segregation engine, a node communication software application, and a node service adapter software application as well as the module software platform may include a module communication software application. Also, the node rule generation software application may be implemented using one or more fuzzy logic algorithms and the node rule check software application may be implemented using one or more fuzzy logic algorithms.

Within the embodiments described below, an exemplary method for providing one or more virtual networks for a plurality of services is disclosed. The method may include a step of receiving one or more service applications and storing the one or more service applications in a node storage device. A further step in the method may be providing a sub-layer within a plurality of data packets to communicate virtual private network information. An additional step in the method may be generating a tunnel or connection to provide a virtual network for a service using a communication software application. Another step in the method may be reducing cross-service interference between a plurality of services using a service segregation engine.

The method may further include receiving a plurality of data packets at a network node through one or more communication interfaces with the network node having one or more node processors and a node storage device. An additional step of the method may be decapsulating the plurality of data packets into different data layers for each of the data packets using an inspection software application implemented by the one or more node processors. Another step in the method may be reading the data layers using a node reader software application. Also, the method may include a step for analyzing one of the data layers obtained from the plurality of data packets and storing the data layer information in the node storage device using a node sorting software application.

The method may further include accessing the data layers of the plurality of data packets from the node storage device and processing the data layers using a node analyzing software application. Additional steps in the method may be receiving custom rules through a node user interface using a node user input software application and generating derived rules based on processed data layer information and the custom rules using a rule generation algorithm. Another step in the method may be accessing the data layer information of the plurality of data packets, the custom rules, and the derived rules from the node storage device, analyzing the data layer information for each of the plurality of data packets, the custom rules, and the derived rules to determine a node rule trigger event using a node rule check software application. Further steps in the method may be receiving the node rule trigger event from the node rule check software application and generating a node rule trigger event notification based on the node rule trigger event using a node notification generator software application. Other steps in the method may be receiving the node rule trigger event notification and forwarding the node rule trigger event notification to the one of the one or more node communication interfaces using a node user output software application. Also, the node rule generation software application may be implemented using one or more fuzzy logic algorithms and the node rule check software application may be implemented using one or more fuzzy logic algorithms.

Within the embodiments described below, an exemplary device for providing one or more virtual networks for a plurality of services is disclosed. The device may include a secure access node coupled to a wide area communication network and a premises communication network. The secure access node may have a node software platform, one or more node processors, a node storage device, and one or more node communication interfaces. Further, the secure access node may receive a plurality of data packets through one or the one or more node communication interfaces. The node software platform may execute on one of node processors and may include a node deep packet inspection engine, a node rules generation engine, a node rule check, and notification generation engine, a node service segregation engine, a node communication software application, and a node service adapter software application.

The foregoing summary is illustrative only and is not intended to be in any way limiting. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features will become apparent by reference to the drawings and the following detailed description.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1A is an exemplary network architecture providing multiple services to premises over communication networks;

FIG. 1B-1E show exemplary network architectures for individual virtual networks;

FIG. 2 shows an exemplary software platform for a primary service provider server that provides aspects of providing multiple services to premises over communication networks;

FIG. 3 shows an exemplary architecture for a secure access node that provides aspects of providing multiple services to premises over communication networks;

FIG. 4 shows an exemplary software platform for a secure access control module that provides aspects of providing multiple services to premises over communication networks;

FIG. 5 shows an exemplary software platform for a service module that provides aspects of providing multiple services to premises over communication networks;

FIG. 6 illustrates exemplary communication software and service segregation aspects of providing multiple services to premises over communication networks;

FIG. 7 illustrates exemplary service adaptation aspects of providing multiple services to premises over communication networks;

FIG. 8 illustrates an exemplary deep packet inspection engine that may be used to provide additional service features in providing multiple services to premises over communication networks;

FIG. 9 illustrates exemplary aspects of the secure access node that provide additional service features in providing multiple services to premises over communication networks;

FIG. 10 illustrates exemplary aspects of the primary service provider server that provide additional service features in providing multiple services to premises over communication networks;

FIG. 11 illustrates an exemplary rule generation engine that may be used to provide additional service features to providing multiple services in premises over communication networks;

FIG. 12 illustrates an exemplary rule check and notification generation engine that may be used to provide additional service features in providing multiple services to premises over communication networks;

FIGS. 13A-13D are exemplary flowcharts that show example methods of providing multiple services to premises over communication networks.

DETAILED DESCRIPTION

In the following detailed description, reference is made to the accompanying drawings, which for a part hereof. In the drawings, similar symbols typically identify similar components, unless context dictates otherwise. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting. Other embodiments may be utilized, and other changes may be made, without departing from the spirit or scope of the subject matter presented herein. It will be readily understood that the aspects of the present disclosure, as generally described herein, and illustrated in the Figures, can be arranged, substituted, combined, separated, and designed in a wide variety of difference configurations, all of which are explicitly contemplated herein. Further, in the following description, numerous details are set forth to further describe and explain one or more embodiments. These details include system configurations, block module diagrams, flowcharts, and accompanying written description. While these details are helpful to explain one or more embodiments of the disclosure, those skilled in the art will understand that these specific details are not required in order to practice the embodiments.

Traditionally, terminal network devices and/or service provider servers generate, control, and maintain service virtual networks that may be inefficient and expensive. The present application discloses systems, devices, and methods for providing virtual networks for multiple services. Aspects of the disclosed systems, devices, and methods have intermediate network nodes generate, control, and maintain virtual service networks for individual and business consumers. The intermediate nodes may be customer premises equipment or a server of a primary service provider (e.g. Internet Service Provider). Further, while maintaining the virtual service networks, the intermediate network nodes may inspect data packets of different services and collect service application data. Consequently, the intermediate nodes may process the collected data to maintain segregation between services, increase security from third party intrusion into the virtual service networks, generate additional robust service features by analyzing data across different services, and provide consumer behavioral data to enhance user experiences and security on e-commerce activities. In addition, having virtual network management and control for multiple services implemented by intermediate nodes in a network such as several primary server (e.g. primary service provider server) or several customer premises equipment has the further advantages of having the virtual network management and control mechanism residing in only a few intermediate nodes rather than a comparatively larger number of terminal network devices (e.g. end point devices) and service providers servers (e.g. secondary servers).

FIG. 1A is an exemplary network architecture 100 providing multiple services to premises over communication networks. The network architecture 100 may include a wide area network (WAN) infrastructure 104 that provides network connectivity using communications links (124, 128, 132 and 134) between a primary service provider server (e.g. primary server) 112 and one or more secondary service provider servers (e.g. secondary servers) (108, 116, 120, and 122). A wide area network may be network of nodes or computers whose communication links spans a broad area including crossing metropolitan, regional, national, and continental political and geographic boundaries. Examples of wide area networks may include the Internet, wireless wide area communication networks, metropolitan area network, cellular networks, and WiMAX networks. The Wide Area Network Infrastructure 104 may include network elements or nodes that facilitate network connectivity between terminal network devices and servers (e.g. primary server, secondary servers, etc.) as shown by the network architecture 100 in FIG. 1A. Examples of such network elements or nodes include routers, switches, multiplexers, servers, etc. Communication links between network elements and nodes that are part of the WAN infrastructure such as the communication links (124, 128, 132, and 134) between the secondary servers (108, 116, 120, and 122) and the primary server 112 may incorporate packet switching technology, circuit switching technology, or a combination of both.

In addition to providing network connectivity between the primary server 112 and the secondary servers (108, 116, 120, and 122), the WAN infrastructure 104 provides network connectivity between the primary server and one or more secure access nodes (160 and 184). Although FIG. 1A shows the primary server 112 connected to two secure access nodes (160 and 184), persons of ordinary skill in the art would recognize that the primary server may be connected to additional secure access nodes. As with the other communication links (124, 128, 132, and 134) pictured in FIG. 1A, the communication links (136 and 140) between the secure access nodes (160 and 184) and the primary server 112 may incorporate packet switching technology, circuit switching technology, or a combination of both. Further, the exemplary network 100 shows that secondary servers may communicate to end point devices (152, 156, 164, 176, 180, and 188) (e.g. terminal devices) through the WAN infrastructure 104, the primary server 112, one or more secure access nodes (160 and 184) and one or more premises networks (148 and 172).

Each of the secure access nodes (160 and 184) reside on customer premises. One secure access node 160 resides in a home customer premises 144 and another secure access node 184 resides in a business customer premises 168. The home customer premises 144 may include a premises communication network 148 connecting the secure access node 160 to multiple terminal network or end point devices (152, 156, and 164). Alternatively, the business customer premises 168 may include a premises communication network 172 connecting the secure access node 184 to multiple terminal network or end point devices (176, 180, and 188). Further, each of the secure access nodes may have multiple communication interfaces supporting different protocols (e.g. USB, Ethernet, Firewire, Bluetooth, WiFi, etc.). One communication interface on each of the secure access nodes (160 and 184) may be connected to the WAN Infrastructure 104. Another communication interface may be connected to their respective premises networks (148 and 172).

A primary service provider that may own or operate the primary server 112 may be an Internet Service Provider (ISP), for example, or any multi-service operator (MSO) such as a cable television company, telephone company, or any other company that may also be an ISP. The primary server may provide services to one or more end point devices located on customer premises (144 and 168) over the WAN infrastructure 104. For example, the primary server 112 may provide Internet access, email, network security as well as other types of features or services. An end point device, such as a personal computer 156 may utilize such services. In addition, secondary service providers may own and operate the secondary servers (108, 116, 120, and 122) to provide their respective services. Secondary service providers may provide services such as Voice-over-Internet-Protocol (VoIP), energy management, premises security, electronic security, different types of e-commerce, media streaming and storage, etc. In FIG. 1A, for example, a secondary server 108 may provide energy management services, another secondary server 116 may provide premises security services, a third secondary server 120, may provide e-commerce services, and a fourth secondary server 122 may provide VoIP services to one or more end point devices (152, 156, 164, 176, 180, and 188).

For example, in the exemplary network 100, end point device 152 and end point device 176 may represent customer premises equipment for a premises (home or office) security service provider. The end point devices (152 and 176) may include sensors and alarms that are located throughout the premises (home 144 or office 168) that provide information to the premises server 116. Another example in the network 100 may be that end point device 156 is a home computer and end point device 188 is an enterprise computer. A primary server 112 may be a server owned and operated by an Internet Service Provider (ISP) or MSO and provide the end point device 156 and end point device 188 with a variety of services such as providing Internet access, email, and network security. Further, a secondary server 120 may be provide e-commerce services such as providing an electronic market place for the users of end point devices (156 and 188) to buy and sell goods. An additional example in network 100 may be that end point device 180 may be a premises energy management system and secondary server 108 may be energy management server. End point device 180 may include different sensors that provide the energy management server 120 with energy consumption and other energy management information for different portions of the office 168. A further example may be that end point device 164 is a VoIP telephone and the secondary server 122 is a VoIP server providing voice telephony services (e.g. telephony, caller identification, voicemail, etc.) to the home 144.

FIG. 1B shows exemplary network architectures 101 for two different individual virtual networks (103 and 105). The network elements and communication networks shown in FIG. 1A are used in illustrating virtual networks (103 and 105) shown in FIG. 1B. A virtual network 103 includes primary server 112, wide area network 104, secure access node 160, premises network 148, and end point device 156. As mentioned in describing FIG. 1A, the primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO and provide the end point device 156 with a variety of services such as provide Internet access, email, and network security. The virtual network segregates the services provided by the ISP (e.g. Internet access, email, and network security, etc) from other services received by the end point device 156 such as, for example, e-commerce services from secondary server 120. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 160 may generate and maintain the virtual network 103 and segregates the ISP services from other services provided to the end point device 156.

Further, a virtual network 105 includes primary server 112, wide area network 104, secure access node 160, premises network 148, and end point device 152. The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO. The end point device 152 may be customer premises equipment for a premises (home or office) security service provider that may include sensors and alarms located throughout the premises (home 144) that provide information to the premises server 108. In traditional networks, the primary server 112 may not be involved in any of the services provided by the premises security service provider. However, in the virtual network 105, the primary server 112 and/or the secure access node 160 may segregate the premises security service from other services (email, network security, e-commerce, energy management, VoIP, etc.) as a virtual network. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 160 may generate and maintain the virtual network 105 and segregates the premises security services from other services provided to the end point device 152.

FIG. 1C shows exemplary network architectures 107 for two different individual virtual networks (109 and 111). The network elements and communication networks shown in FIG. 1A are used in illustrating virtual networks (109 and 111) shown in FIG. 1C. A virtual network 109 includes primary server 112, wide area network 104, secure access node 184, premises network 172, and end point device 180. The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO and provide the end point device 180 with a variety of services such as provide Internet access, email, and network security. The virtual network segregates the services provided by the ISP (e.g. Internet access, email, and network security, etc) from other services received by the end point device 180 such as, for example, e-commerce, premises security, and energy management services from a secondary server. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 184 may generate and maintain the virtual network 109 and segregates the ISP services from other services (e.g. energy management services) provided to the end point device 180.

Further, a virtual network 111 includes primary server 112, wide area network 104, secure access node 184, premises network 172, and end point device 176. The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO. The end point device 176 may be customer premises equipment for a premises (home or office) security service provider that may include sensors and alarms located throughout the premises (office 168) that provide information to the premises server 108. In traditional networks, the primary server 112 may not be involved in any of the services provided by the premises security service provider. However, in the virtual network 111, the primary server 112 and/or the secure access node 184 may segregate the premises security service from other services (email, network security, e-commerce, energy management, VoIP, etc.) as a virtual network. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 184 may generate and maintain the virtual network 111 and segregates the premises security services from other services provided to the end point device 176.

FIG. 1D shows exemplary network architectures 113 for two different individual virtual networks (115 and 117). The network elements and communication networks shown in FIG. 1A are used in illustrating virtual networks (115 and 117) shown in FIG. 1D. A virtual network 115 includes primary server 112, wide area network 104, secure access node 160, premises network 148, and end point device 156 as well as secondary server 3 (120). The secondary server 3 (120) may be owned or operated by an e-commerce service provider and may allow an end point device user to buy and sell goods in an electronic marketplace, for example. The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO and provide the end point device 156 with a variety of services such as provide Internet access, email, and network security. However, the virtual network segregates the services provided by the ISP (e.g. Internet access, email, and network security, etc) from other services received by the end point device 156 such as e-commerce services from secondary server 108. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 160 may generate the virtual network 115 and segregates the ISP services from the e-commerce services provided to the end point device 156. In addition, the software platform on the primary server 112 or a software and hardware platform residing on the secure access node 160 may provide additional features to a particular service or across a range of services that are segregated in virtual networks as will be described in the present disclosure.

Further, a virtual network 117 includes primary server 112, wide area network 104, secure access node 160, premises network 148, and end point device 152 as well as secondary server 2 (116). The primary server 112 may be owned and operated by an Internet Service Provider (ISP). The end point device 152 may be customer premises equipment for a premises (home or office) security service provider that may include sensors and alarms located throughout the premises (home 144) that provide information to secondary server 2, the premises security server 116. In a traditional network, the primary server 112 may not be involved in any of the services provided by the premises security service provider. However, in the virtual network 117, the primary server 112 and/or the secure access node 160 may segregate the premises security service from other services (email, network security, e-commerce, energy management, VoIP, etc.) as a virtual network. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 160 may generate and maintain the virtual network 117 and segregates the premises security services from other services provided to the end point device 152. In addition, the software platform on the primary server 112 or a software and hardware platform residing on the secure access node 160 may provide additional features to a particular service or across a range of services that are segregated in virtual networks as will be described in the present disclosure.

FIG. 1E shows exemplary network architectures 119 for two different individual virtual networks (121 and 123). The network elements and communication networks shown in FIG. 1A are used in illustrating virtual networks (121 and 123) shown in FIG. 1E. A virtual network 121 includes primary server 112, wide area network 104, secure access node 184, premises network 172, and end point device 188 as well as secondary server 3 (120), an e-commerce server 120. The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO and provide the end point device 188 with a variety of services such as provide Internet access, email, and network security. The virtual network segregates the services provided by the ISP (e.g. Internet access, email, and network security, etc) from other services received by the end point device 188 such as, for example, e-commerce services from secondary server 120. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 184 may generate and maintain the virtual network 121 and segregates the ISP services from e-commerce services as well as the other services provided to the end point device 188. In addition, the software platform on the primary server 112 or a software and hardware platform residing on the secure access node 184 may provide additional features to a particular service or across a range of services that are segregated in virtual networks as will be described in the present disclosure.

Further, a virtual network 123 includes primary server 112, wide area network 104, secure access node 184, premises network 172, and end point device 176 as well as secondary server 2 (116). The primary server 112 may be owned and operated by an Internet Service Provider (ISP) or MSO. The end point device 176 may be customer premises equipment for a premises (home or office) security service provider that may include sensors and alarms located throughout the premises (office 168) that provide information to the premises server 116. In traditional networks, the primary server 112 may not be involved in any of the services provided by the premises security service provider. However, in the virtual network 123, the primary server 112 and/or the secure access node 184 may segregate the premises security service from other services (email, network security, e-commerce, energy management, VoIP, etc.) as a virtual network. A software platform residing on the primary server 112 or a software and hardware platform residing on the secure access node 184 generate the virtual network 123 and segregates the premises security services from other services provided to the end point device 176. In addition, the software platform on the primary server 112 or a software and hardware platform residing on the secure access node 184 may provide additional features to a particular service or across a range of services that are segregated in virtual networks as will be described in the present disclosure.

FIG. 2 shows an exemplary software platform 220 for a primary service provider server 212 that provides aspects of providing multiple services to premises over communication networks. The primary server 212 executes a server software platform 220 on one or more server processors and stores the server software platform 220 and any associated data in a server storage device 236. The one or more processors may be represented as a processor bank 234. Persons of ordinary skill in the art would understand that the one or more processors comprising the processor bank 234 may be distributed across the primary server hardware and may not be limited to being co-located next to one another. Further, the server software platform 220 includes a server deep packet inspection engine 222, a server rules generation engine 224, a server rule check and notification generation engine 226, a server service segregation engine 228, a server communication software application 230, and a server service adapter software application 232.

A primary server 212 may receive and transmit one or more data packets through one or more communication interfaces for multiple services provided to one or more end point devices. Segregating services into different virtual networks as well as providing additional features across the multiple services may require the primary server 212 to read the data within each of the one or more data packets received. Generally, the server deep packet inspection engine 222 allows the primary server to read the data within the received data packets. The data read from the one or more data packets may be stored in the server storage device 236.

To provide additional features across multiple services, the server software platform 220 may generate service rules using the server rules generation engine. Service rules are generated based on the data read from the data packets received and may be called derived rules. Custom rules may also be inputted by a user or by a service provider to the primary server 212 using a communication interface such as user interface (e.g. web browser, etc.). Service rules (e.g. derived rules, custom rules, etc.) may also be stored in the server storage device 236.

The additional features may be delivered to a service subscriber by the primary server 212 using a server rule check and notification generation engine 226. The additional features may be incorporated into one or more notifications based on a rule check or violation when analyzing the data in the received data packets. For example, a rule may be derived or inputted by a user that states no e-commerce activity may be done at a home computer end point device between 9 am to 5 pm on weekdays. However, the primary server reads received data packets indicating that a home computer is conducting an e-commerce activity at 10:03 am on a weekday. Consequently, primary server 212 may send a notification to either the home computer or the e-commerce secondary server stating a rule violation occurred.

The server software platform 220 may further include a server service segregation engine 228 that reduces the cross-service interference between different services relayed by the primary server 212 from one or more secondary service provider servers to one or more end point devices. Additionally, the server service segregation 228 engine may assist in generating and maintain a virtual network for a specific service (e.g. premises security, energy management, VoIP, e-commerce, etc.) in conjunction with other aspects of the server software platform 220 such as a server communication software application 230 and a server adapter software application 232. The server service segregation engine 228 may prevent cross-service interference, for example, when an energy management server may be attempting to shut down one or more components of a premises security system such as premises security alarms, sensors, etc.

The server communication software 230 of a server software platform may also be involved in generating and maintaining a virtual network for a specific service. The communication software may generate and maintain a communication tunnel between the primary server 212 and a secure access node to an end point device. Alternatively, the communication software may generate and maintain a communication connection such as in a virtual LAN or using MPLS technology.

In addition, the server software platform 220 may have server service adapter software 232 that may provide an adaption layer between an application layer and a network layer, or between any two layers of a communication protocol stack. Such an adaption layer provides additional functionality to the primary server 212 and a secure access node. The adaptation layer provides a mechanism for the primary server 212 and a secure access node to generate and maintain a virtual network for a specific service and reduce cross-service interference.

FIG. 3 shows an exemplary architecture for a secure access node 300 that provides aspects of providing multiple services to premises over communication networks. The exemplary secure access node 300 in FIG. 3 has eight service modules (302, 304, 306, 308, 310, 312, 314, and 316). Persons of ordinary skill in the art would recognize that a secure access node may include more or less than the exemplary number of eight service modules shown in FIG. 3. A service module within a secure access node 300 may be coupled to one or more end point devices that receive one or more services from a primary server or one or more secondary servers across a communication network (e.g. premises network, WAN, etc.). The end point devices may be coupled to a service module through one or more communication interfaces. Each communication interface may support a different communication technology (USB, Firewire, Bluetooth, Ethernet, WiFi etc.).

In addition to the eight service modules (302, 304, 306, 308, 310, 312, 314, and 316), the secure access node 300 may have a secure access control module 320. Further, the service modules (302, 304, 306, 308, 310, 312, 314, and 316) may communicate with the secure access control module 320 through a secure access node interconnection bus 318. Persons of ordinary skill in the art would understand that the secure access node interconnection bus 318 is an exemplary communication mechanism between the secure access control module 320 and the service modules (302, 304, 306, 308, 310, 312, 314, and 316) and that any other appropriate internode communication mechanism may be used. Further, the secure access node may have one or more communication interfaces 322 to communicate with one or more communication networks (e.g. WAN, LAN, premises network, etc.) that deal with different technology (Ethernet, DSL, PON, Cable, IMS, etc,).

FIG. 4 shows an exemplary software platform 420 for a secure access control module 400 that provides aspects of providing multiple services to premises over communication networks. The secure access control module 400 executes a server software platform 420 on one or more node processors and stores the node software platform 420 and any associated data in a node storage device 436. The one or more processors may be represented as a processor bank 434. Persons of ordinary skill in the art would understand that the one or more processors comprising the processor bank 434 may distributed across the secure access node hardware and may not be limited to being co-located next to one another. The node software platform 420 includes a node deep packet inspection engine 422, a node rules generation engine 424, a node rule check and notification generation engine 426, a node service segregation engine 428, a node communication software application 430, and a node service adapter software application 432.

The secure access control module 400 may receive and transmit one or more data packets though one or more communication interfaces for multiple services provided to one or more end point devices. Segregating services into different virtual networks as well as providing additional features across the multiple services may require the secure access control module 400 to read the data within each of the one or more received data packets. Generally, the node deep packet inspection engine 422 allows the secure access control module 400 to read the data within the received data packets. The data read from the one or more data packets may be stored in the node storage device 436.

To provide additional features across multiple services, the node software platform 420 may generate service rules using the server rules generation engine. Service rules are generated based on the data read from the received data packets and are called derived rules. Custom rules may also be inputted by a user or by a service provider to the secure access control module 400 using a communication interface such as user interface (e.g. web browser, etc.). Service rules (e.g. derived rules, custom rules, etc.) may also be stored in the node storage device 436.

The additional features may be delivered to a service subscriber by the secure access control module 400 using a node rule check and notification generation engine 426. The additional features may be incorporated into one or more notifications based on a rule check or violation when analyzing the data in the received data packets. For example, a rule may be derived or inputted by a user that states no e-commerce activity may be conducted at a home computer end point device between 9 am to 5 pm on weekdays. However, the secure access control module 400 reads received data packets indicating that a home computer is conducting an e-commerce activity at 10:03 am on a weekday. The secure access control module 400 may send a notification to either the home computer or the e-commerce secondary server, either via a primary server or directly, stating a rule violation occurred.

The node software platform 420 may further include a node service segregation engine 428 that reduces the cross-service interference between different services relayed by the secure access control module 400 to one or more end point devices. Additionally, the node service segregation 428 engine may assist in generating and maintain a virtual network for a specific service (e.g. premises security, energy management, VoIP, e-commerce, etc.) in conjunction with other aspects of the node software platform 420 such as a node communication software application 430 and a node adapter software application 432. The node service segregation engine 428 may prevent cross-service interference, for example, when an energy management server may be attempting to shut down one or more components of a premises security system such as premises security alarms, sensors, etc.

The node communication software 430 of a node software platform 420 may also be involved in generating and maintaining a virtual network for a specific service. The communication software 430 may generate and maintain a communication tunnel between the secure access control module 400 and a primary server to an end point device. Alternatively, the communication software 430 may generate and maintain a communication connection such as in a virtual LAN or using MPLS technology.

In addition, the node software platform 420 may have node service adapter software 432 that may provide an adaption layer between an application layer and a network layer or between any two layers of a communication protocol stack. Such an adaption layer provides additional functionality to the secure access control module 400 and a primary server. The adaptation layer provides a mechanism for the secure access control module 400 and a primary server to generate and maintain a virtual network for a specific service and reduce cross-service interference.

FIG. 5 shows an exemplary module software platform for a service module 500 that provides aspects of providing multiple services to premises over communication networks. The service module 500 executes a module software platform on one or more module processors and stores the module software platform and any associated data in a module storage device 536. The one or more module processors may be represented as a processor bank 534. Persons of ordinary skill in the art would understand that the one or more module processors comprising the processor bank 534 may distributed across the service module hardware and may not be limited to being co-located next to one another. The module software platform includes a module communication software application 530 and a module service adapter software application 532.

The module communication software 530 of a module software platform may be involved in generating and maintaining a virtual network for a specific service. The communication software 530 may generate and maintain a communication tunnel between an end point device, the service module 500, secure access control module and a primary server. Alternatively, the communication software 530 may generate and maintain a communication connection such as in a virtual LAN or using MPLS technology.

In addition, the module software platform may have module service adapter software 532 that may provide an adaption layer between an application layer and a network layer or any two layer of a communication protocol stack. Such an adaption layer provides additional functionality to the service module 500, a secure access control module, and a primary server. The adaptation layer provides a mechanism for the service module, secure access control module, and a primary server to generate and maintain a virtual network for a specific service and reduce cross-service interference.

Persons of ordinary skill in the art would understand that functionality incorporated in the service module 500 may be performed by a secure access control module and that service module software platform may not be needed to generate and maintain a virtual network for a specific service.

FIG. 6 illustrates exemplary communication software and service segregation aspects of providing multiple services to premises over communication networks. Further, FIG. 6 shows an exemplary network 600 having a primary server 645 coupled a secure access node 639 having a secure access control module 635 and one or more service modules (615 and 625) across a wide area network 643. Each of the service modules (615 and 625) may be coupled to one or more endpoint devices (605 and 610) across a premises network (not shown).

The primary server 645 may have a communication software application 655 and a service segregation engine 657 both as part of a server software platform Further, the secure access control module 635 may have a node communication software application 640 and a node service segregation engine 642 both as part of a node software platform. Additionally, each of the service modules (615 and 625) may have a communication software application (620 and 630) as part of a module software platform.

The communication software applications (615, 625, 640, and 655) residing on each service module (615 and 625), the secure access control module 635, and the primary server 645 may provide tunneling or connection capabilities to generate and maintain a virtual network for each particular service provided to the end point devices (605 and 610). Examples of tunneling technology that may be used by the communication software applications (615, 625, 640, and 655) may include, but are not limited to, Generic Routing Encapsulation (GRE), Layer 2 Tunneling Protocol (L2TP), Point-to-Point Tunneling Protocol (PPTP) as well as other plaintext and non-plaintext tunneling protocols. Alternatively, the communication software applications (615, 625, 640, and 655) may utilize other communication software technologies to generate aspects of a virtual network for a particular service. These communication technologies may include Multiprotocol Label Switching (MPLS) technology or other communication technology that generates and maintains a connection using either a circuit-switched or packet-switched technology known to persons of ordinary skill in the art.

The server service segregation engine 655 and the node service segregation engine 642 may also generate and maintain aspects of a virtual network for a specific service. For example, the server service segregation engine 655 and the node service segregation engine 642 may provide additional security and decrease or reduce cross-service interference between different services supported by different virtual networks by the secure access node 639 and the primary server 645. The additional security may be provided by cryptographic protocol schemes known to persons of ordinary skill in the art that include, but are not limited to, symmetric-key algorithms such as Data Encryption Standard (DES), Triple DES, and Advanced Encryption Standard (AES) as well as public-key algorithms such as a RSA algorithm and the like. Additional security may also be provided by monitoring the state of the communication protocols such as TCP states of initiation and termination of a connection to determine that states of connection progress properly. Communication protocols may be further strengthened using proprietary protocols between the primary server 645 and service access control module 635, service module 615 and 625. Further, the server service segregation engine 657 and the node service segregation engine 642 may utilize security protocols such as IPsec and Microsoft Point-to-Point Encryption (MPPE). Persons of ordinary skill in the art would understand that IPsec may be used in conjunction with Layer 2 Tunneling Protocol and MPPE may be used in conjunction with PPTP.

In addition, the server service segregation engine 657 and the node service segregation engine 642 may also provide additional features to reduce cross-service interference. For example, the server service segregation engine 657 and the node service segregation engine 642 may prevent an energy management service provider from shutting off an alarm or sensor as part of a premises security system. Another example may be the server service segregation engine 657 and the node service segregation engine 642 preventing a home computer user from conducting e-commerce transactions between 9 am and 5 pm on weekdays.

The functionality of the server service segregation engine 657 and the node service segregation engine 642 as well as the communication software applications (615, 625, 640, and 655) may be illustrated by concentric tunnel diagram 659 shown in FIG. 6. Further, FIG. 6 shows a communication pipe 660 illustrating a connection or communication link between the primary server 645 and the secure access control module 635. Moreover, the concentric tunnel diagram 659 illustrates the tunneling/connection functionality as well as aspects of the virtual network capability provided by the server service segregation engine 655 and the node service segregation engine 642 as well as the communication software applications (615, 625, 640, and 655). Particularly, communication pipe 665 within communication pipe 660 may illustrate a tunnel or connection supporting a particular service, the tunnel or connection provided by the server service segregation engine 657 and the node service segregation engine 642 as well as the communication software applications (615, 625, 640, and 655) while communication pipe 670 may be another tunnel or connection supporting a particular service, the tunnel or connection provided by the server service segregation engine 657 and the node service segregation engine 642 as well as the communication software applications (615, 625, 640, and 655).

FIG. 7 illustrates exemplary service adaptation aspects of providing multiple services to premises over communication networks. Specifically, FIG. 7 shows an exemplary network 700 that includes a primary server 716 coupled to a secure access control module 710 across a wide area network (WAN) 714. Further, the secure access control module 710 may be coupled to a service module 706. In addition, the service module 706 may be coupled to an end point device 702 across a premises network. The primary server 716 may have a server service adapter software application 721 as part of the primary server's server software platform. Also, the primary server 716 may have server service application software 720 that provides service functionality to the end point device 702. For example, the end point device 702 may be a home computer and the primary server 716 may provide email services to such an end point device 702. Thus, the end point device may have a client service software application 704 that supports the features provided by the service server software application 720. For example, the client service software application 704 may be a client email software application that supports the email services provided by the service server software application 720.

In addition, FIG. 7 shows an exemplary functional block diagram 723 that illustrates the functionality of the server service adapter software application 721, the node service adapter software application 712, and the module service adapter software application 708. Particularly, the exemplary functional block diagram 723 shows a server protocol stack 772 implemented by the primary server 716, a node protocol stack 770 implemented by the secure access control module 710, a module protocol stack 768 implemented by the service module 706, and an end point device protocol stack 766 implemented by the end point device 702.

An application layer 756 may be at the top of the server protocol stack 772 implemented by the service server software application 718. Below the application layer 756 may be an application sub-layer 757 implemented by the server service adapter software application 721. Under the application sub-layer 757, maybe a transport layer 758, network layer 760, datalink layer 762, and physical layer 764.

Further, an application layer 744 may be at the top of the node protocol stack 712 residing on the secure access control module 712. Below the application layer 746 may be an application sub-layer 746 implemented by the node service adapter software application 712 residing on the secure access control module 710. Under the application sub-layer 746, may be a transport layer 748, network layer 750, datalink layer 752, and physical layer 754.

In addition, an application layer 732 may be at the top of the module protocol stack 768 residing on the service module 706. Below the application layer 732 may be an application sub-layer 734 implemented by the module service adapter software application 708 residing on the service module 706. Under the application sub-layer 734, may be a transport layer 736, network layer 738, datalink layer 740, and physical layer 742.

Also, an application layer 722 may be at the top of the end point device protocol stack 766 implemented by the client service software application residing on the end point device 702. Below the application layer 732 may be a transport layer 724, network layer 726, datalink layer 728, and physical layer 730.

The server service adapter software application 721, node service adapter software application 712, and the module service adapter software application 708 may provide a proprietary or standard sub-layer within the server protocol stack 772, node protocol stack 770, and module protocol stack 768 to generate and maintain a virtual network for a specific service between the primary server 716 and the end point device 702. For example, the server service adapter software application 721, node service adapter software application 712, and the module service adapter software application 708 may be encryption software to provide increased security (e.g. DES, RSA, proprietary methods, etc.), proprietary commands to reduce cross-service interference (e.g. preventing energy management service to turn off aspects of premises security service), and quality of service tags to provide additional service features to the end point device (e.g. prioritizing streaming video over e-commerce transactions). Persons of ordinary skill in the art would recognize that the sub-layers (723, 746, and 734) shown under the application layer (756, 744, and 732) in their respective protocol stacks (772, 770, and 768) in FIG. 7 may be implemented under any layer (e.g. application, transport, network, datalink, physical, etc.). Further, persons of ordinary skill in the art would understand that functionality depicted in the service module 706 may also be alternatively implemented by the secure access control module 710.

FIG. 8 illustrates an exemplary deep packet inspection engine 822 that may be used to provide additional service features in providing multiple services to premises over communication networks. Persons of ordinary skill in the art would recognize that the deep packet inspection engine can modify and process data packets and may include functions such as count, copy, forward drop, modification, and other actions in addition to the functions described below. Further, the functions may include proprietary functions to implement novel aspects of the systems, devices, and methods disclosed.

Particularly, FIG. 8 shows a data packet 802 having an application layer 812 payload and encapsulated by a transport header 810 and a transport trailer 814 to comprise a transport layer, a network header 808 and a network trailer 816 to comprise a network layer, a datalink header 806 and a datalink trailer 818 to comprise a datalink layer, and a physical header 804 and a physical trailer 820 to comprise a physical layer. The data packet 802 may be received by a deep packet inspection engine 822. The deep packet inspection engine may be part of a server software platform residing on a primary server as shown in FIG. 2 or a node software platform residing on a secure access control module as shown in FIG. 4.

The deep packet inspection engine 822 may include an inspection software application 824, a reader software application 826, and a sorting software application 828. The inspection application 824 may decapsulate the received data packet 802 into its different layers (headers and trailers) corresponding to a protocol stack as shown in the decapsulating functional diagram 830. The reader software application 826 may read the data at each layer of the data packet such as an application layer 840, a transport layer (838 and 842), a network layer (836 and 844), a datalink layer (834 and 846) and a physical layer (832 and 848). The sorting software application 828 may analyze the data in the one or more layers (e.g. application, transport, network, datalink, and physical) and store the data in one or more memory subcomponents within a storage device.

FIG. 9 illustrates exemplary aspects of the secure access node 920 that provide additional service features in providing multiple services to premises over communication networks. FIG. 9 shows a functional block diagram 900 illustrating functions of a sorting software application 930 that may be part of a deep packet inspection engine 925 which in turn may be part of a secure access node software platform. The deep packet inspection engine may receive data packets from one or more end point devices (905, 910, and 915) and inspects and reads the data packets using an inspection software application and a reader software application, respectively, as discussed in FIG. 8. The sorting software application 930 may analyze the data in the one or more layers (e.g. application, transport, network, datalink, and physical) of the received data packets and store the data in one or more memory subcomponents (935, 945, and 950) within a storage device 955 residing on the secure access node 920. Data read from the received data packets may be stored in different memory subcomponents (935, 945, and 950) according to different categories within the storage device 955 based on the analysis by the sorting software application 930. For example, data may be stored in different categories based on service type (e.g. premises security, energy management, e-commerce, etc.) or by data layer type (e.g. application, transport, network, datalink, physical, etc.).

FIG. 10 illustrates exemplary aspects of the primary service provider server 1032 that provide additional service features in providing multiple services to premises over communication networks. FIG. 10 shows a functional block diagram 1000 illustrating functions of a sorting software application 1036 that may be part of a deep packet inspection engine 1034 which in turn may be part of a primary server software platform. The deep packet inspection engine 1034 may receive data packets from one or more secure access nodes (1010, 1020, and 1030) each coupled to one or more end point devices (1004, 1006, and 1008, 1014, 1016, and 1018, and 1024, 1026, and 1028) across a premises network. Further, the deep packet inspection engine 1034 inspects and reads the data packets using an inspection software application and a reader software application, respectively, as discussed in FIG. 8. The sorting software application 1036 may analyze the data in the one or more layers (e.g. application, transport, network, datalink, and physical) of the received data packets and store the data in one or more memory subcomponents (1038, 1040, and 1042) within a storage device 1044 residing on the primary server 1032. Data read from the received data packets may be stored in different memory subcomponents (1038, 1040, and 1042) according to different categories within the storage device 1044 based on the analysis by the sorting software application 1036. For example, data may be stored in different categories based on service type (e.g. premises security, energy management, e-commerce, etc.) or by data layer type (e.g. application, transport, network, datalink, physical, etc.). Data may be stored according to other types of categories such as by secure access node (1010, 1020, and 1020) or by end point device type (e.g. computer, premises security equipment, energy management equipment, etc.).

FIG. 11 illustrates an exemplary rule generation engine 1120 that may be used to provide additional service features to providing multiple services in premises over communication networks. The exemplary functional block diagram 1100 shown in FIG. 11 depicts different functional components of a network element such as a primary server or a secure access node. The functional components may be one or more communication interfaces 1105 that may include a user interface 1110 such as an internet browser, and a server/node communication interface such as an Ethernet, LAN, WiFi, Bluetooth, etc. interface 1115. The one or more communication interfaces 1105, including the user interface 1110 and the server/node communication interface 1115, may be coupled to the rule generation engine 1120 which is part of the server/node software platform. The rule generation 1120 may include an analyzing software application 1125, a user input software application 1130, and a rule generator software application 1135. Additionally, the rule generation engine 1120 may be coupled to a network element storage device 1140 having one or more memory subcomponents (1145, 1150, and 1155). The storage device 1140 as well as the one or more memory subcomponents (1145, 1150, and 1155) may store data from data packets received by the network element (e.g. primary server or secure access node). Further, the data may be stored into different memory subcomponents (1145, 1150, and 1155) according to different categories such as service type (e.g. premises security, energy management, e-commerce, etc.), data layer type (e.g. application, transport, network, datalink, physical, etc.), secure access node type, or by end point device type. In addition, a user may provide user data through the user interface 1110 using a user input software application 1130 that categorizes and stores the user data into different memory subcomponents (1145, 1150, and 1155) within the storage device 1140.

The analyzing software application 1125 may access the storage device 1140 as well as the one or more memory subcomponents (1145, 1150, and 1155) to obtain the data from the received data packets and the user data. Further, the analyzing software application 1125 provides an analysis of the received data packet data and the user data and forwards the analysis to the rule generator software application 1135. Consequently, the rule generator software application 1135 determines service rules based on the data from the received data packets called derived rules and service rules based on user data called custom rules. The derived rules and the custom rules may be stored in to different memory subcomponents (1145, 1150, and 1155) within the storage device 1140 according to different categories.

For example, the analyzing software application 1125 may access the data from the received data packets and determine that an end point device such as a home computer does not conduct e-commerce between 9 am-5 pm on most days. Thus, based on such analysis the rule generator software application 1135 may generate a derived rule to prevent e-commerce activity on the end point device between 9 am-5 pm every day. However, user data may be obtained by the analyzing software application 1125 that states that e-commerce activity can be conducted on the end point device between 9 am-5 pm on weekends. Hence, the rule generator software application 1135, based on the user data may develop a custom rule to prevent e-commerce activity on the end point device between 9 am-5 pm only on weekdays.

Another example may be that the analyzing software application 1125 observes multiple facets of communications based on time of day, source address filter, traffic pattern, etc. to classify a threat level or to specify a type of threat of a received packet; Further, fuzzy logic techniques may be used, because the secure access node or primary server does not have necessary or sufficient information regarding either content or protocol of connections passing through a platform (e.g. server software platform, node software platform, etc.). In many cases, a rule check or rule violation may not be severe and the primary server's or secure access node's response may need to be proportional to the rule check or rule violation detected. As a result, fuzzy logic becomes a useful method to include into the analyzing software application 1135. A rule check fuzzy set to threat type/threat level fuzzy set relationship matrix may be established based on prior experiences using Cartesian Product Method, for example, and be stored in the memory device 1140. As a further example, a user may not place a restriction on time of day or day of week to conduct e-commerce, but that prior usage over the past month indicated that the user never conducted e-commerce during a weekday from 9 am to 5 pm. Such a fuzzy logic may be derived and used by a rule check and notification generation engine.

FIG. 12 illustrates an exemplary rule check and notification generation engine 1220 that may be used to provide additional service features in providing multiple services to premises over communication networks. The exemplary functional block diagram 1200 shown in FIG. 12 depicts different functional components of a network element such as a primary server or a secure access node. The functional components may be one or more communication interfaces 1205 that may include a user interface 1210 such as an internet browser, and a server/node communication interface such as an Ethernet, LAN, WiFi, Bluetooth, etc. interface 1215. The one or more communication interfaces 1205, including the user interface 1210 and the server/node communication interface 1215, may be coupled to the rule check and notification generation engine 1220 which may be part of the server/node software platform. The rule check and notification generation engine 1220 may include a rule check software application 1225, a user output software application 1230, and a notification generator software application 1235. Additionally, the rule check and notification generation engine 1220 may be coupled to a network element storage device 1240 having one or more memory subcomponents (1245, 1250, and 1255). The storage device 1240 as well as the one or more memory subcomponents (1245, 1250, and 1255) may store service rules including derived rules and custom rules provided by a rule generation engine as discussed when describing FIG. 11. Further, the service rules as well as data from data packets received through the one or more communication interfaces may stored into different memory subcomponents (1245, 1250, and 1255) according to different categories such as service type (e.g. premises security, energy management, e-commerce, etc.), data layer type (e.g. application, transport, network, datalink, physical, etc.), secure access node type, or by end point device type.

The rule check software application 1225 accesses the service rules as well as the data from the received data packets from the different memory subcomponents (1245, 1250, and 1255) within the storage device 1240. Further, the rule check software application 1225 determines whether a trigger event has occurred, such as rule violation, based on the service rules and the received packet data. If so, the rule check software application 1225 sends the trigger event (e.g. violation) to the notification generator software application 1235. Based on the trigger event (e.g. violation), the notification generator software application 1235 generate a trigger event notification and forwards the trigger event notification to the user output software application 1230. Additionally, the user output software application 1230 may provide the trigger event notification to the user interface 1210 to be displayed to a user.

For example, a service rule may be obtained by the rule check software application 1225 that states no e-commerce activity may be conducted between 9 am-5 pm on weekdays (prohibited time period) on a particular end point device. However, the rule check software application 1225 also obtains data from received data packets that shows the particular end point device conducting e-commerce activity at 10:03 am on a Monday. Thus, e-commerce activity is being conducted during a prohibited time according to the service rule. A trigger event along with data associated with the prohibited activity as well as the service rule may be forwarded to the notification generator software application 1235. Based on the trigger event along with prohibited activity data as well as the service rule, the notification generator software application 1235 generates an exemplary trigger event notification that may state “Warning: Prohibited E-Commerce Activity Conducted” that is forwarded to the user output software application 1230 which in turn provides the exemplary trigger event notification to the user interface 1210 to be displayed to a user. Additionally, the network element software platform may solicit a user password as part of the exemplary trigger event notification for a user to continue conducting e-commerce activity during the prohibited time period.

Another example, the rule check software application 1225 on a secure access node observes multiple facets of communications based on time of day, source address filter, traffic pattern, etc. to check a threat level or a type of threat of an incoming packet based on rules generated by a rules generation engine. Further, fuzzy logic techniques may be used because a secure access node or primary server may not have necessary or sufficient information regarding either content or protocol of connections passing through a server or node software platform. In some cases, a rule check or violation may not be severe and a primary server's or secure access node's response may need to be proportional to the rule check or violation detected. As a result, fuzzy logic becomes a useful method to incorporate into the primary server or secure access node software platform. A rule check fuzzy set to threat type/threat level fuzzy set relationship matrix may be established based on prior experiences examined by the rules generation engine. An incoming rule violating packet's violation fuzzy set may be processed based on the relationship matrix stored in the memory device 1240. By using a composite operation in the fuzzy logic, the threat level and threat type may be determined. Such a determination may be forwarded to the notification generator application 1235. Further to the example, a user may not place a restriction on time of day and day of week to conduct e-commerce, but that prior usage over the past month indicated that the user never conducted e-commerce during a weekday from 9 am to 5 pm. Such a fuzzy logic rule may be derived and used by a rule check software application. Further, a user may attempt to conduct e-commerce at 10:03 am on a Monday. A notification may be generated based on the derived fuzzy logic rule described above such as; “Warning—Potentially Unusual Activity being attempted”.

Another example may be each primary server managing multiple secure access nodes each of which resides in a subscriber's premises. Information, including a number of rejected packets and usage of some popular Internet sites may be collected and compiled. Further, a rule check software application on each primary server may collect rule violation statistics of all managed secure access nodes and may compile a network wide security condition using a fuzzy set representation which may be an n-tuple of threat level of each secure access node the primary server manages on a per time period basis. This n-tuple information may be processed using each premises' preference to common Internet sites usage relationship matrix stored in the memory device 1240 to determine a potential threat level to commonly used sites on networks or subscribed secondary services such that rules (e.g. access control list) may be applied using the notification generator application 1235. Consequently, Internet resources and services are better protected although limited knowledge or limited details of a scenario are made known to the primary server. Persons of ordinary skill in the art would recognize that the fuzzy logic algorithms known in the art as well as those disclosed through the above examples or understood by those persons skilled in the art may be incorporated in other aspects or embodiments of the present disclosure.

FIGS. 13A-13D are exemplary flowcharts that show example methods of providing multiple services to premises over communication networks. In FIG. 13A, the example method shown may include a step for receiving one or more service applications, as shown in block 1304. The service applications may be received by a primary server or a secure access node and stored in a storage device or memory. Each of the one or more service applications may be received from the primary server or from a secondary server. For example, the one or more service applications may be an email application received from a primary server, an e-commerce application received from a secondary server, an energy management service application received from another secondary server, or other service applications.

A further step in the example method may be providing a data sub-layer to one or more data packets, as shown in block 1308, by a network element using a service adapter software application that is part of the network elements software platform. The network element may be a primary server or a secure access node. For example, the service adapter software application may be encryption software to provide increased security (e.g. DES, RSA, etc.), proprietary commands to reduce cross-service interference (e.g. preventing energy management service to turn off aspects of premises security service), and quality of service tags to provide additional service features to the end point device (e.g. prioritizing streaming video over e-commerce transactions). Persons of ordinary skill in the art would recognize that the data sub-layer may not only be implemented under the application layer but also may be implemented under any communication protocol layer (e.g. transport, network, datalink, physical, etc.).

Another step in the example method may be generating a connection or tunnel, as shown in block 1312, by a network element using a communication software application that is part of the network element's software platform. The network element may be a primary server or a secure access node. Examples of tunneling technology that may be used by the communication software applications may include, but are not limited to, Generic Routing Encapsulation (GRE), Layer 2 Tunneling Protocol (L2TP), Point-to-Point Tunneling Protocol (PPTP) as well as other plaintext and non-plaintext tunneling protocols. Alternatively, the communication software application may utilize other communication software technologies to generate aspects of a virtual network for a particular service. These communication technologies may include Multiprotocol Label Switching (MPLS) technology or other communication technology that generates and maintains a connection using either a circuit-switched or packet-switched technology.

An additional step in the example method may be reducing cross-service interference, as shown in block 1316, using a service segregation engine that is part of a network element's software platform. The network element may be either a primary server or a secure access node. For example, the segregation engine may reduce cross-service interference by preventing an energy management service provider from shutting off an alarm or sensor as part of a premises security system.

Referring to FIG. 13B, the example method may include receiving data packets by a primary server or secure access node through one or more communication interfaces, as shown in block 1320. The data packets may be stored in a storage device within the primary server or secure access node. A further step in the example method may be decapsulating the data packets, as shown block 1324, using an inspection software application of a deep packet inspection engine residing on the primary server or secure access node as part of a software platform. Decapsulating may include separating the data from each communication data layer (e.g. physical, datalink, network, transport, application, etc.) of the data packet. An additional step in the example method may be reading data from the different layers of the decapsulated data packet, as shown in block 1328, using a reader software application of the deep packet inspection engine residing on the primary server or secure access node. Another step in the example method may be sorting the data from the different layers of the decapsulated data packet into different categories using a sorting software application of the deep packet inspection engine, as shown in block 1332. Further, the sorting software application may store the sorted data in a storage device according to different categories, as shown in block 1336. The storage device may have different memory subcomponents such that each category of sorted data may be stored in a different memory subcomponent.

Referring to FIG. 13C, the example method may include accessing sorted data from the different memory subcomponents within a storage device, as shown in block 1344, using an analyzing software application of a rules generation engine that is part of a primary server's or secure access node's software platform. A further step in the example method may be processing the sorted data to determine end point device behavior, as shown in block 1348. For example, the analyzing software application may access the sorted data and determine that an end point device such as a home computer does not conduct e-commerce between 9 am-5 pm on most days.

An additional step in the example method may be receiving custom rules from user software application that may be part a rule generation engine through a user interface of the primary server or secure access node, as shown block 1352. For example, a custom rule may be to allow e-commerce activity between 9 am-5 pm on weekends. Another step in the example method may be generating derived rules using a rule generator software application that may be part of the rule generation engine, as shown in block 1356. The derived rules may be generated based on the analysis of the sorted data provided by an analyzing software application and based on the received custom rules. An exemplary derived rule may be preventing e-commerce activity between 9 am-5 pm on weekdays. Note that custom rules and derived rules may be called services rules collectively.

Referring to FIG. 13D, the example method may include determining a trigger event using a rule check software application of a rule check and notification generation software application that may be part of a primary server's or secure access node's software platform, as shown in block 1360. The rule check software application may access received data from data packets as well as the service rules from a storage device. A trigger event may be determined based on the received data and/or service rules. For example, a service rule may be obtained by the rule check software application that states no e-commerce activity may be conducted between 9 am-5 pm on weekdays on a particular end point device. However, the rule check software application also obtains data from received data packets that shows the particular end point device is conducting e-commerce activity at 10:03 am on a Monday. Thus, the rule check software application may determine and generate a trigger event based on e-commerce activity is being conducted during a prohibited time according to the service rule.

A further step in the example method may be generating a trigger event notification using a notification generator software application as part of the rule check and notification generation software application, as shown in block 1368. For example, based on the exemplary trigger event based on prohibit e-commerce conduct by an end point device, the notification generator software application generates an exemplary trigger event notification that may state “Warning: Prohibited E-Commerce Activity Conducted.” An additional step in the method may be forwarding the trigger event notification to a user output software application that is part of the rule check software application, as shown in block 1372. The user output software application may display the trigger event notification to a user through a user interface.

In general, it should be understood that the circuits described herein may be implemented in hardware using integrated circuit development technologies, or yet via some other methods, or the combination of hardware and software objects that could be ordered, parameterized, and connected in a software environment to implement different functions described herein. For example, the present application may be implemented using a general purpose or dedicated processor running a software application through volatile or non-volatile memory. Also, the hardware objects could communicate using electrical signals, with states of the signals representing different data.

It should be further understood that this and other arrangements described herein are for purposes of example only. As such, those skilled in the art will appreciate that other arrangements and other elements (e.g. machines, interfaces, functions, orders, and groupings of functions, etc.) can be used instead, and some elements may be omitted altogether according to the desired results. Further, many of the elements that are described are functional entities that may be implemented as discrete or distributed components or in conjunction with other components, in any suitable combination and location.

The present disclosure is not to be limited in terms of the particular embodiments described in this application, which are intended as illustrations of various aspects. Many modifications and variations can be made without departing from its spirit and scope, as will be apparent to those skilled in the art. Functionally equivalent methods and apparatuses within the scope of the disclosure, in addition to those enumerated herein, will be apparent to those skilled in the art from the foregoing descriptions. Such modifications and variations are intended to fall within the scope of the appended claims. The present disclosure is to be limited only by the terms of the appended claims, along with the full scope of equivalents to which such claims are entitled. It is to be understood that this disclosure is not limited to particular methods, reagents, compounds compositions, or biological systems, which can, of course, vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting.

With respect to the use of substantially any plural and/or singular terms herein, those having skill in the art can translate from the plural to the singular and/or from the singular to the plural as is appropriate to the context and/or application. The various singular/plural permutations may be expressly set forth herein for sake of clarity.

It will be understood by those within the art that, in general, terms used herein, and especially in the appended claims (e.g., bodies of the appended claims) are generally intended as “open” terms (e.g., the term “including” should be interpreted as “including but not limited to,” the term “having” should be interpreted as “having at least,” the term “includes” should be interpreted as “includes but is not limited to,” etc.). It will be further understood by those within the art that if a specific number of an introduced claim recitation is intended, such an intent will be explicitly recited in the claim, and in the absence of such recitation no such intent is present. For example, as an aid to understanding, the following appended claims may contain usage of the introductory phrases “at least one” and “one or more” to introduce claim recitations. However, the use of such phrases should not be construed to imply that the introduction of a claim recitation by the indefinite articles “a” or “an” limits any particular claim containing such introduced claim recitation to embodiments containing only one such recitation, even when the same claim includes the introductory phrases “one or more” or “at least one” and indefinite articles such as “a” or “an” (e.g., “a” and/or “an” should be interpreted to mean “at least one” or “one or more”); the same holds true for the use of definite articles used to introduce claim recitations. In addition, even if a specific number of an introduced claim recitation is explicitly recited, those skilled in the art will recognize that such recitation should be interpreted to mean at least the recited number (e.g., the bare recitation of “two recitations,” without other modifiers, means at least two recitations, or two or more recitations). Furthermore, in those instances where a convention analogous to “at least one of A, B, and C, etc.” is used, in general such a construction is intended in the sense one having skill in the art would understand the convention (e.g., “a system having at least one of A, B, and C” would include but not be limited to systems that have A alone, B alone, C alone, A and B together, A and C together, B and C together, and/or A, B, and C together, etc.). In those instances where a convention analogous to “at least one of A, B, or C, etc.” is used, in general such a construction is intended in the sense one having skill in the art would understand the convention (e.g., “a system having at least one of A, B, or C” would include but not be limited to systems that have A alone, B alone, C alone, A and B together, A and C together, B and C together, and/or A, B, and C together, etc.). It will be further understood by those within the art that virtually any disjunctive word and/or phrase presenting two or more alternative terms, whether in the description, claims, or drawings, should be understood to contemplate the possibilities of including one of the terms, either of the terms, or both terms. For example, the phrase “A or B” will be understood to include the possibilities of “A” or “B” or “A and B.”

In addition, where features or aspects of the disclosure are described in terms of Markush groups, those skilled in the art will recognize that the disclosure is also thereby described in terms of any individual member or subgroup of members of the Markush group.

As will be understood by one skilled in the art, for any and all purposes, such as in terms of providing a written description, all ranges disclosed herein also encompass any and all possible subranges and combinations of subranges thereof. Any listed range can be easily recognized as sufficiently describing and enabling the same range being broken down into at least equal halves, thirds, quarters, fifths, tenths, etc. As a non-limiting example, each range discussed herein can be readily broken down into a lower third, middle third and upper third, etc. As will also be understood by one skilled in the art all language such as “up to,” “at least,” “greater than,” “less than,” and the like include the number recited and refer to ranges which can be subsequently broken down into subranges as discussed above. Finally, as will be understood by one skilled in the art, a range includes each individual member. Thus, for example, a group having 1-3 cells refers to groups having 1, 2, or 3 cells. Similarly, a group having 1-5 cells refers to groups having 1, 2, 3, 4, or 5 cells, and so forth.

While various aspects and embodiments have been disclosed herein, other aspects and embodiments will be apparent to those skilled in the art. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims. 

1. A system, comprising: (a) a first communication network; (b) one or more nodes coupled to the first communication network wherein the one or more nodes devices includes a primary server and one or more secure access nodes (c) one or more terminal devices wherein each terminal device is connected to a corresponding secure access node through a second communication network; (d) each node having: (i) one or more communication interfaces wherein at least one of the one or more communication interfaces is coupled to the first communication network; (ii) one or more processors; (iii) one or more storage devices coupled to the one or more processors; (iv) one or more software applications stored in the one or more storage devices and executed by the one or more processors; (e) wherein the primary server provides and controls one or more primary services delivered to an end user using one or more terminal devices through the secure access node; (f) wherein the primary server allows one or more secondary services from one or more secondary servers to be delivered to one or more terminal devices through a secure access node; (g) wherein the one or more software applications: (i) provide the primary server and one or more secondary servers access one or more terminal devices to deliver one or more primary services and one or more secondary services; (ii) control one or more service functions of each primary service and secondary service; and (iii) reduce cross-service interference among services including the one or more primary services and one or more secondary services; (iv) provide a management function including maintenance, diagnostics and administration; (h) wherein the cross-service interference among services is reduced by using a service segregation module based on fuzzy logic rules; (i) wherein the software applications use fuzzy logic rules to determine integrity of service messages and service information flowing from a service to other services, and each violation of the fuzzy logic rules is flagged and reported to a primary server's management function; (j) wherein the primary server's management function updates the fuzzy logic rules in one or more nodes based on flagged violation.
 2. The system of claim 1, further comprising: a device service adapter software application, executed by the device, wherein the device service adapter software application: receives a first service application message for the service; checks integrity of the service application message using fuzzy logic rules; modifies the service application message using reliability and security improvement schemes including embedding of service identification data; provides modified encapsulated first service application message to the one or more secure access nodes.
 3. The system of claim 2, wherein the reliability and security improvement schemes is selected from a group consisting of the use of error correcting codes, variation of inter-packet gaps, network coding, use of conventional security schemes, fuzzy logic, and any combination thereof.
 4. The system of claim 2, wherein secure access node software applications: checks the modified encapsulated service application message from the primary server using fuzzy logic rules and non-fuzzy logic rules; and de-capsulates the modified encapsulated service application message and transmits the de-capsulated service application message to a corresponding service function.
 5. The system of claim 2, wherein the first service application message received from a device that is selected from a group consisting of the one or more nodes and one or more terminal devices.
 6. The method of claim 2, wherein the device is selected from the group consisting of a primary server and a secure access node.
 7. The system of claim 1, wherein the secure access node software applications further comprising: a secure access node user input software application that receives custom rules through a first secure access node communication interface of the one or more secure access node communication interfaces, and a secure access node rule generation software application that receives the custom rules and generates derived rules based on the custom rules and processed data using a secure access node rule generation algorithm; wherein the derived rules include service segregation rules to reduce cross-service interference and security enhancement rules increasing security of one or more primary services and one or more secondary services.
 8. The system of claim of 1, wherein the service is selected from the group consisting of one or more primary services and secondary services.
 9. The system of claim 1, wherein one or more primary services and one or more secondary service are selected from the group consisting of video services, telephone services, Internet services, wireless services, energy management, IT backup, alarm and security services, tele-medicine, e-education, third party applications, and combination thereof.
 10. The system of claim 1, wherein the terminal devices are selected from the group consisting of TV, tablet, smart-phone, printer, security camera, or any other device with an appropriate communication interface for connection to the secure access node, and a combination thereof.
 11. A device, comprising: (a) one or more communication interfaces wherein at least one of the one or more communication interfaces is coupled to a first communication network; (b) one or more processors; (c) one or more storage devices coupled to the one or more processors; (d) one or more software applications stored in the one or more storage devices and executed by the one or more processors; (e) wherein the device allows one or more primary services and one or more secondary services to be delivered to one or more terminal devices; (f) wherein the one or more software applications: (i) provide a primary server and one or more secondary servers access to one or more terminal devices to deliver one or more primary services and one or more secondary services; (ii) control one or more service functions of each primary service and secondary service; and (iii) reduce cross-service interference among the one or more primary services and one or more secondary services; (iv) provide a management function including maintenance, diagnostics and administration; (h) wherein the cross-service interference among services is reduced by using a service segregation module based on fuzzy logic rules; (i) wherein the software applications use fuzzy logic rules to determine integrity of service messages and service information flowing from a service to other services, and each violation of the fuzzy logic rules is flagged and reported to a primary server's management function; (j) wherein the primary server's management function updates the fuzzy logic rules in one or more nodes based on flagged violation.
 12. The device of claim 11, further comprising: a device service adapter software application, executed by the device, wherein the device service adapter software application: receives a first service application message for the service; checks integrity of the service application message using fuzzy logic rules; modifies the service application message using reliability and security improvement schemes including embedding of service identification data; provides modified encapsulated first service application message to the one or more secure access nodes.
 13. The device of claim 12, wherein the reliability and security improvement schemes is selected from a group consisting of the use of error correcting codes, variation of inter-packet gaps, network coding, use of conventional security schemes, fuzzy logic, and any combination thereof.
 14. The device of claim 12, wherein device software applications: checks the modified encapsulated service application message from the primary server using fuzzy logic rules and non-fuzzy logic rules; and de-capsulates the modified encapsulated service application message and transmits the de-capsulated service application message to a corresponding service function.
 15. The device of claim 12, wherein the first service application message is received from a device that is selected from a group consisting of the one or more nodes and one or more terminal devices.
 16. The device of claim 11, further comprising: a device user input software application that receives custom rules through a device communication interface of the one or more device communication interfaces, and a device rule generation software application that receives the custom rules and generates derived rules based on the custom rules and processed data using a device rule generation algorithm; wherein the derived rules include service segregation rules to reduce cross-service interference and security enhancement rules increasing security of one or more primary services and one or more secondary services.
 17. The device of claim of 11, wherein the service is selected from the group consisting of one or more primary services and secondary services.
 18. The device of claim 11, wherein one or more primary services and one or more secondary service are selected from the group consisting of video services, telephone services, Internet services, wireless services, energy management, IT backup, alarm and security services, tele-medicine, e-education, third party applications, and combination thereof.
 19. The device of claim 11, wherein the terminal devices are selected from the group consisting of TV, tablet, smart-phone, printer, security camera, or any other device with an appropriate communication interface for connection to the secure access node, and a combination thereof.
 20. The device of claim 11, wherein the device is selected from the group consisting of a primary server and a secure access node.
 21. A method, comprising: (a) allowing one or more primary services and one or more secondary services to be delivered to one or more terminal devices through a secure access node; (b) providing a primary server and one or more secondary servers access to one or more terminal devices to deliver one or more primary services and one or more secondary services; (c) controlling one or more service functions of each primary service and secondary service; and (d) reducing cross-service interference among the one or more primary services and one or more secondary services (e) providing a management function including maintenance, diagnostics and administration; (f) wherein the cross-service interference among services is reduced by using a service segregation module based on fuzzy logic rules; (g) determining, using fuzzy logic rules, integrity of service messages and service information flowing from a service to other services, and, each violation of the fuzzy logic rules is flagged and reported to a primary server's management function; (h) updating, by the primary server's management function, the fuzzy logic rules in one or more nodes based on flagged violation.
 22. The method of claim 21, further comprising: receiving a first service application message for the service by a device service adapter software application; checking integrity of the service application message using fuzzy logic rules by the device service adapter software application; modifying the service application message using reliability and security improvement schemes including embedding of service identification data by the device service adapter software application; providing modified encapsulated first service application message to the one or more secure access nodes by the device service adapter software application.
 23. The method of claim 22, wherein the reliability and security improvement schemes is selected from a group consisting of the use of error correcting codes, variation of inter-packet gaps, network coding, use of conventional security schemes, fuzzy logic, and any combination thereof.
 24. The method of claim 22, further comprising: checking a service application message using fuzzy logic rules and non-fuzzy logic rules using one or more device software applications; and de-capsulating the modified encapsulated service application message and transmitting the de-capsulated message to a corresponding service function using one or more device software applications.
 25. The method of claim 22, wherein the first service application message is received from a device that is selected from a group consisting of the one or more nodes and one or more terminal devices.
 26. The method of claim 21, further comprising: receiving, by a device user input software application, custom rules through a device communication interface of one or more device communication interfaces, and generating, by a device rule generation software application, derived rules based on the custom rules and processed data using a device rule generation algorithm; wherein the derived rules include service segregation rules to reduce cross-service interference and security enhancement rules increasing security of one or more primary services and one or more secondary services.
 27. The method of claim of 21, wherein the service is selected from the group consisting of one or more primary services and secondary services.
 28. The method of claim 21, wherein one or more primary services and one or more secondary service are selected from the group consisting of video services, telephone services, Internet services, wireless services, energy management, IT backup, alarm and security services, tele-medicine, e-education, third party applications, and combination thereof.
 29. The method of claim 21, wherein the terminal devices are selected from the group consisting of TV, tablet, smart-phone, printer, security camera, or any other device with an appropriate communication interface for connection to the secure access node, and a combination thereof.
 30. The method of claim 21, wherein the device is selected from the group consisting of a primary server and a secure access node. 